A convective heat transfer system for use with a fluid with particles, including a fluid channel having a wall and being capable of transferring the fluid, and a field emitter operable to emit a time-varying field into the fluid channel such that, when the fluid is in the channel, the time varying field affects a portion of the particles to change the rate of heat transfer between the channel and the fluid. The fluid can be a slurry with suspended field reactive particles. The system can include a plurality of field emitters located along the walls of the fluid channel, to vary the field and manipulate the distribution of the particles within the slurry, thereby changing the heat transfer characteristics of the system. The field can be an electric field or a magnetic field. The fluid channel can be disposed in a heat transfer system.
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10. A convective heat transfer method comprising:
flowing a fluid having magnetic particles therein into a fluid channel having a wall; and
emitting a time-varying magnetic field from a field emitter into the fluid channel thereby affecting a portion of the particles to change a rate of heat transfer between the wall of the fluid channel and the fluid,
wherein said emitting a time-varying magnetic field includes increasing the time varying field, thereby attracting the portion of the particles to said wall sufficiently to transfer heat from said wall to the portion of the particles, and subsequently decreasing the time varying field, thereby releasing the portion of the particles away from said wall thereby breaking up a boundary layer in the fluid adjacent to said wall and transporting heat away from said wall.
1. A convective heat transfer system to be used with a fluid having particles therein, said system comprising:
a fluid channel having a wall and being capable of transferring the fluid and the particles in the fluid; and
means for emitting a time-varying field into said fluid channel such that, when the fluid is in the channel, the time varying field affects a portion of the particles to change a rate of heat transfer between said wall of said fluid channel and the fluid, such that an increase in the time varying field attracts the portion of the particles to said wall sufficiently to transfer heat from said wall to the portion of the particles and a decrease in the time varying field releases the portion of the particles away from said wall thereby breaking up a boundary layer in the fluid adjacent to said wall and transporting heat away from said wall.
2. The system of
3. The system of
4. The system of
5. The system of
the fluid in said fluid channel; and
particles in said fluid.
9. The system of
a chiller system for cooling the fluid, the chiller arranged to transfer the cooled fluid into the fluid channel.
11. The method of
12. The system of
receiving said fluid having magnetic particles therein from a chiller before said flowing the fluid having magnetic particles therein into the fluid channel.
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Heat transfer limitations and optimization have been an engineering design constraint for decades. Thermal management has been a key consideration in the design and development of military hardware in the past century. More recently, cooling effectiveness has become a very important technical challenge and is one of the limiting factors in the further development of a range of military related disciplines including electronic, high-energy weapon and propulsion systems. Microelectronic components are particularly susceptible to thermal management problems and have become an integral component in most military systems. Many of these components cannot operate at elevated temperatures resulting in a thermal management system becoming a key consideration.
Convective heat transfer is one way of addressing thermal management. Convective heat transfer is the heat transfer process that is executed by the flow of a fluid over a surface of a medium. Convective heat transfer includes advective heat transfer, which is based on the velocity of the fluid flow compared to the medium, and conductive heat transfer, which is based on static fluid adjacent to the medium. In convective heat transfer, the fluid acts as a carrier for the energy that it draws from (or delivers to) the surface of the medium.
For purposes of a simplistic explanation of heat transfer in the system of
There are many ways to specify the types of convection. The flow over the surface can be specified as internal, e.g., with pipes or ducts, or external, e.g., with fins. The motive force behind the bulk fluid motion can be forced, e.g., by a fan or pump, or natural, e.g., driven by buoyancy forces caused by fluid density changes with temperature. The flow can be further classified as single-phase, wherein the fluid does not change phase or multi-phase, e.g., boiling or condensation.
There are many specific characteristics of the flow of a fluid that greatly affect the heat transfer rate from/to the medium's surface, but the two categories that govern the effectiveness of single-phase forced convective heat transfer are: 1) the rate of conduction of energy (heat) to/from the medium surface; and 2) the rate of conveyance of energy toward/away from the surface with the mass flow of the bulk fluid. The rate of conduction is dictated by both the thermal conductivity of the fluid and the temperature of the fluid in the boundary layer. The thermal conductivity of the fluid is a temperature dependent physical property of the fluid that is being used in the convection process. The temperature of the fluid in the boundary layer is influenced by the amount of heat transferred, the specific heat of the fluid and the flow characteristics in the boundary layer. Poor flow characteristics will not allow the fluid in the boundary layer to be replaced by the bulk fluid. The major factors that determine the rate of energy conveyance are the mass flow rate of the bulk fluid and the specific heat capacity of the fluid.
The best convective heat transfer occurs when the fluid properties and flow conditions are optimized. The optimal fluid properties are high thermal conductivity and high specific heat capacity. The flow conditions that favor optimal convective heat transfer include high local fluid velocity at the medium's surface. Unfortunately, it is difficult to optimize both the thermal conductivity and specific heat capacity of a fluid, and the naturally occurring boundary layer limits the flow near the medium's surface.
Two specific areas of convective heat transfer research address the fluid property and surface flow problems. These two areas include the use of nanofluids and the use of magnetic fields with magnetrohetrological fluids. Both have limited success in enhancing the rate of convective heat transfer.
Nanofluids are conventional fluids with tiny particles therein that may typically be no larger than several nanometers. The particles are usually of high thermal conductivity and are added to the fluid to increase the bulk thermal conductivity of the fluid. In general, the particles are metal or metal oxides, such as for example Cu, CuO and Al2O3. A significant increase in thermal conductivity has been reported for various volume fractions of particles suspended in different fluids. Experiments performed utilizing nanofluids have shown an increase of convective heat transfer rate when compared to the same fluid without nanoparticles.
The bulk majority of the research in magnetic fields used to enhance heat transfer is focused on the hydrodynamic manipulation of magnetorhetrological fluids (ferrofluids). Much of the numerical and theoretical investigation centers on a disruption of the boundary layer through the use of a constant magnetic field acting on a ferrofluid. In all of these cases the fluid is assumed to remain homogeneous in particle composition. Another area of research utilizes magnetic fields and soft magnetic particles to reduce the disadvantage of inefficient gas-solid two-phase flow. The magnetic particles are attracted to the wall, which has a temperature that is higher than the temperature of the bulk fluid flowing by the wall. The attracted particles are heated above their Curie point by thermal conduction and then are carried away by the flow. By conservation of energy, the temperature of the wall is generally decreased by an amount proportional to the amount of heat carried away, whereas the temperature of the bulk fluid is increased by an amount proportional to the amount of heat carried away.
Neither the use of nanofluids nor constant magnetic fields, described above, optimize the potential for improving convective heat transfer performance.
What is needed is system and method for improving convective heat transfer performance.
It is an object of the present invention to improve convective heat transfer performance by providing combined thermal conductivity characteristics of certain solids with the high specific heat values of appropriate fluids to enhance the overall heat transfer characteristics of a heat exchanger.
In order to achieve at least the above-discussed object, in accordance with one aspect of the present invention, a system for transferring heat away from the surface of a heat exchanger is presented. The system comprises a fluid channel disposed in a heat exchanger unit, containing a slurry as the convective heat transfer medium. The slurry comprises an appropriate fluid with field reactive particles suspended therein. Additionally, field emitters are located along the walls of the fluid channel to manipulate the dispersion of the particles within the slurry. By attracting the field reactive particles directly to the walls of the fluid channel, heat can be effectively transferred to/from the particles with minimal thermal resistance. Releasing the particles into the bulk fluid allows the heat to be transferred to/from the high specific heat fluid very effectively because of the large total surface area of the particles when separated within the bulk fluid. The attracting and releasing the particles from the walls of the fluid channel has the additional advantage of breaking up the boundary layer and allowing fluid from the core bulk flow to come in more direct contact with the wall.
In one exemplary embodiment, the slurry comprises ferromagnetic (or other materials effected by magnetic fields) particles and a liquid used as the convective heat transfer medium. A time-varying magnetic field is produced in a fluid channel of the heat exchanger to cause the ferromagnetic particles to be attracted to the walls of the fluid channel. The field would remain energized long enough to attract the ferromagnetic particles to the walls and also allow the heat to be transferred to/from the ferromagnetic particles. The ferromagnetic particles are highly conductive and therefore are able to quickly conduct heat directly from the wall with their superior thermal conductivity, which may be as much as three orders of magnitude over common heat transfer liquids. The particles are then released back into the fluid and transfer heat into/out of the bulk liquid. With a magnetic field utilized as the particle manipulative motive force, particle removal may be enhanced by: de-energizing the magnetic field that initially attracted the particle to the wall; and then energizing of a magnetic field that is displaced spatially from the field that initially attracted the particle to the wall. Although the particles can be removed from the wall by the hydrodynamic forces of the flowing fluid, the additional use of a magnetic field would help ensure the removal of particles from the solid surface.
In another exemplary embodiment, the slurry comprises particles that are affected by electric fields and a liquid used as the convective heat transfer medium. A time-varying electric field is produced in a fluid channel of the heat exchanger to cause the particles to be attracted to the walls of the fluid channel. The field would remain energized long enough to attract the particles to the walls and also allow the heat to be transferred to/from the particles. The particles are highly conductive and therefore are able to quickly conduct heat directly from the wall with their superior thermal conductivity. The particles are then released back into the fluid and transfer heat into/out of the bulk liquid. With an electric field utilized as the particle manipulative motive force, particle removal may be enhanced by: de-energizing the electric field that initially attracted the particle to the wall; and then energizing an electric field that is displaced spatially from the field that initially attracted the particle to the wall. Further, particle removal may be additionally enhanced by reversing the polarity of the electric field that initially attracted the particle to the wall. Although the particles can be removed from the wall by the hydrodynamic forces of the flowing fluid, the additional use of an electric field would help ensure the removal of particles from the solid surface.
Superior heat transfer occurs because of the large surface area to volume ratio of the particles after they separate from the wall and mix back into the bulk fluid. Another benefit of the attraction and repulsion of the particles from the walls is the breaking up of the boundary layer close to the fluid channel wall. The breaking up of the boundary layer also enhances the convective heat transfer by helping to transport bulk fluid having the average bulk fluid temperature close to the surface of the fluid channel.
The ferromagnetic particle size can vary, for example from millimeter to nanometer sized particles. It is important that the slurry does not remain homogeneous when acted on by a field because the particles need the ability to be individually attracted to the solid surface.
Additional objects advantages and novel features of the invention are set forth in part in the description which follows, and in part will become apparent to those skilled in the art upon examination of the following or may be learned by practice of the invention. The objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims.
The accompanying drawings which are incorporated in and form a part of the specification, illustrate exemplary embodiments of the present invention and, together with the description, serve to explain the principles of the invention. In the drawings:
In operation, slurry 100 flows through fluid channel 102 creating a boundary layer 105 adjacent to a wall 104. Accordingly, a bulk of the slurry or bulk slurry 107 is the portion of slurry 100 that is flowing, and flows with an average velocity Vf. Wall 104 initially has a temperature t1, whereas the average temperature of bulk slurry 107 is t2. For purposes of simplifying an explanation of an embodiment of the present invention, the case will be discussed wherein t1 is greater than t2, wherein slurry 100 will take heat from wall 104 (e.g., slurry 100 will have a cooling effect on wall 104). One of skill in the art would readily recognize the operation of the present invention in the case of t2 being greater than t1, wherein slurry 100 will give heat to wall 104 (e.g., slurry will have a heating effect on wall 104).
As slurry 100 moves through fluid channel 102, fields are emitted by emitters 106, 108, 110 and 112. The fields attract particles 103 to the walls of fluid channel 102 in the proximity of emitters 106, 108, 110 and 112. The presence of particles 103 adjacent to or in close proximity to fluid channel wall 104 disrupts the boundary layer and enables increased convective heat transfer to slurry 100 across fluid channel wall 104 than would otherwise be possible in the absence of particles 103. Particles 103 are then released from the close proximity to fluid channel wall 104 and disperse throughout fluid 101 to transfer the recently acquired heat to fluid 101. The transferred heat is then carried away from a portion of heat transfer unit 208 as slurry 100 moves through fluid channel 104.
Returning to
Returning to
A working embodiment of a convective heat transfer system will now be described in detail with reference to
A slurry is heated in tubing 402, exits tubing 402 and enters a pump 404. After exiting pump 404, the slurry enters a heat exchanger 406. Heat is removed from the slurry, while in heat exchanger 406, by using chilled water provided by a recirculating chiller 408.
The electrical components of the system of
Returning to
Several data collection runs were performed with apparatus 400 with experimental parameters varied. In some exemplary data collection runs, the slurry comprised oil with iron fillings dispersed therein. The parameters that were varied included concentration of iron fillings to oil, frequency of electromagnet power and current used to energize electromagnets 610, 612, 614 and 616. The results obtained with a constant heat input showed a dramatic decrease in the temperature of the surface of tubing 508 at the midpoint between the inlet and the outlet (the maximum pipe temperature). During these experimental runs, recirculating chiller 408 temperature maintained a temperature of 20° C. and the power inputted into the heaters was 65 W. For one of the more extreme cases, the maximum temperature of tubing 508 (at the tubing midpoint) was measured at 57.2° C., whereas with electromagnets 610, 612, 614 and 618 being deenergized and energized with a time varying square wave, the temperature measured was 42.5° C. Null checks were performed with pure mineral oil to ensure that the instrumentation was not reading incorrectly or the heaters operating improperly because of the fluctuating magnetic fields.
To determine the magnitude of convective heat transfer increase, an experiment was run to determine the amount of heat that could be added and still maintain the same temperature as the full power case with electromagnets 610, 612, 614 and 616 cycling. The maximum increase in heat transfer rate that was obtained with the experimental setup was 80%.
In another exemplary embodiment, an electric field may be used instead of a magnetic field to attract and repel the particles to/from the solid surface. With an electric field the highly thermal conductive particle may comprise, for example, an ionic material or some material that can be manipulated by an electric field. With an electric field utilized as the particle manipulative motive force, particle removal may be enhanced by: de-energizing the electric field that initially attracted the particle to the wall; and then energizing of an electric field that is displaced spatially from the field that initially attracted the particle to the wall. Further, particle removal may be additionally enhanced by reversing the polarity of the electric field that initially attracted the particle to the wall. Although the particles can be removed from the wall by the hydrodynamic forces of the flowing fluid, the use of a separate electric field would help ensure the removal of particles from the solid surface.
In another embodiment, the orientation of the line of magnetic flux used to attract the ferromagnetic particles to the wall is varied in any direction, for example parallel to the wall of tubing 508, such that the magnetic flux lines attract the ferromagnetic particles to the surface of tubing 508.
A system combines the thermal conductivity characteristics of certain solids with the high specific heat values of appropriate fluids to enhance the overall heat transfer characteristics of a heat exchanger. The system comprises a fluid channel disposed in a heat exchanger unit with a slurry as the convective heat transfer medium. The slurry comprises an appropriate fluid with field reactive particles suspended therein. Field emitters are located along the walls of the fluid channel whereby the distribution of particles within the slurry is manipulated to achieve enhanced heat transfer characteristics.
The foregoing description of various preferred embodiments of the invention have been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise forms disclosed, and obviously many modifications and variations are possible in light of the above teaching. The exemplary embodiments, as described above, were chosen and described in order to best explain the principles of the invention and its practical application to thereby enable others skilled in the art to best utilize the invention in various embodiments and with various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims appended hereto.
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